KR200341040Y1 - Multi-layer dydroponic port - Google Patents

Abstract

Disclosed is a stacked nutrient cultivation port in which a plurality of nutrient cultivation ports are vertically stacked so that crops can be cultivated in the respective ports. The stacked nutrient solution cultivation port is made by stacking a plurality of nutrient solution cultivation port having a culture soil supporting the crop. Each of the plurality of nutrient solution cultivation ports has a cylindrical shape in which the top is open and the bottom thereof is sealed, at least one nutrient solution supply pipe is installed in a substantially vertical direction through the lower surface of the nutrient solution cultivation port, The nutrient solution supply pipes of the two nutrient solution cultivation ports are connected to each other at the time of lamination, and the connection portion of the nutrient solution supply pipes adjacent to each other is provided with an outlet through which the nutrient solution can flow out of the nutrient solution supply pipe. Crop growth spheres are formed on at least one side of each nutrient cultivation port. The stacked nutrient solution cultivation port configured as described above allows the high efficiency of crop cultivation by promoting the efficient use of the space of the facility house by arbitrarily adjusting the number of nutrient solution cultivation ports according to the height of the facility house. In particular, the present invention provides an advantage that can easily and efficiently supply the nutrient solution to the nutrient solution cultivation port of each stage laminated through the nutrient solution supply pipe.

Description

Multi-layer dydroponic port

The present invention relates to a stacked nutrient solution cultivation port, and more particularly, to a stacked nutrient solution cultivation port that is able to grow a plurality of nutrient solution cultivation port vertically to each crop.

Applicant has registered in Korean Utility Model Registration No. 20-31339, which relates to stacked nutrient solution repots, by arbitrarily adjusting the number of nutrient solution cultivation ports according to the height of the facility house to efficiently utilize the space in the facility house for high integration of crop cultivation. We have developed a stacked nutrient solution cultivation port.

The present applicant has improved the technology of the nutrient solution cultivation port of the Utility Model Registration No. 20-31339 and developed a technology that makes the operation of supplying nutrient solution to the nutrient solution cultivation port more efficiently and simply.

The object of the present invention is to provide a nutrient solution cultivation port to improve the nutrient solution supply method of the nutrient solution cultivation port to enable efficient and simple nutrient solution supply.

1 is a partial cutaway perspective view showing an embodiment of a stacked nutrient solution cultivation port according to the present invention,

Figure 2 is a cross-sectional view of the stacked nutrient solution culture port of Figure 1,

Figure 3 is an exploded perspective view showing the coupling state of the nutrient solution supply pipe of the stacked nutrient solution cultivation port of Figure 1,

Figure 4 is a perspective view showing a state in which another embodiment of the stacked nutrient solution cultivation port according to the present invention is transported by the conveyor of the nutrient solution cultivation apparatus,

5 is an exploded perspective view of the stacked nutrient solution cultivation port of FIG.

Laminated nutrient solution cultivation port of the present invention for achieving the above object is made by stacking a plurality of nutrient solution cultivation port with a culture soil supporting the crop. Each of the plurality of nutrient solution cultivation ports has a cylindrical shape in which the top is open and the bottom thereof is sealed, at least one nutrient solution supply pipe is installed in a substantially vertical direction through the lower surface of the nutrient solution cultivation port, The nutrient solution supply pipes of the two nutrient solution cultivation ports are connected to each other at the time of lamination, and the connection portion of the nutrient solution supply pipes adjacent to each other is provided with an outlet through which the nutrient solution can flow out of the nutrient solution supply pipe. Crop growth spheres are formed on at least one side of each nutrient cultivation port.

The crop growth zone is set to a size such that the leaf portion of the crop grown on the culture soil can be released to the outside, the outer surface of the nutrient solution cultivation port defining the crop growth zone is inclined upward.

In addition, an upper cover is further provided on an upper portion of the nutrient solution cultivation port located at the top of the stacked nutrient solution cultivation port, and the upper cover has a funnel shape with a cross-sectional area gradually decreasing from the upper part to the lower part, and the upper cover corresponds to the nutrient solution supply pipe. It is preferable that the nutrient solution supply ports are respectively formed at the portions to be provided.

In addition, the lower surface of the nutrient solution cultivation port is preferably formed with a plurality of drain holes for the discharge of the supplied nutrient solution.

In addition, a thrust bearing is interposed in the lower part of the stacked nutrient solution cultivation port, it is preferable that the nutrient solution cultivation port is pivotable freely at the position.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the stacked nutrient solution cultivation port according to the present invention.

1 and 2, the stacked nutrient solution cultivation port is formed by stacking a plurality of nutrient solution cultivation ports 10 having a culture soil 3 supporting a crop. The plurality of nutrient cultivation ports 10 have a cylindrical shape in which the upper part is open and the lower part is closed.

The nutrient solution cultivation port 10 is provided with at least one nutrient solution supply pipe 13. The nutrient solution supply pipe 13 has a lower end portion 13b penetrated through the lower surface 10a of the nutrient solution growing port 10 in a substantially vertical direction. When stacking a plurality of nutrient solution cultivation port, the nutrient solution supply pipe 13 of the two nutrient solution cultivation port 10 adjacent to each other, are interconnected. At the lower end of the nutrient solution supply pipe 13, an enlarged portion 13a having an enlarged cross-sectional area thereof is formed. Therefore, the connection portion between the enlarged portion and the upper end of the adjacent nutrient solution supply pipe is provided with an outlet (arrow part in FIG. 21) through which the nutrient solution filled in the nutrient solution supply pipe can flow out. In order to allow the nutrient solution to flow out through the outlet, the lower end of the nutrient solution supply pipe installed in the lower nutrient solution cultivation port is sealed so that the nutrient solution supplied from the upper part is filled in the interconnected nutrient solution supply pipe.

Meanwhile, as shown in FIG. 3, the upper and lower ends of two mutually adjacent nutrient solution supply pipes 13 are in contact with each other to prevent the nutrient solution outlet from being blocked. Grooves 13b may be formed, and a plurality of uneven portions 13c may be formed along the circumferential direction of the upper end portion. Therefore, even if two nutrient solution supply pipes are contacted by a manufacturing error or an assembly error, the nutrient solution filled in the nutrient solution supply pipe 13 flows out along the gap formed by the uneven portion 13c and the groove 13b of the nutrient solution supply pipe 13. Can be.

The upper cover 11 is coupled to the upper portion of the top nutrient solution cultivation port. The upper cover 11 has a funnel shape and a nutrient solution supply hole 11a is formed at a portion corresponding to the nutrient solution supply pipe 13 of the nutrient solution cultivation port 10. In addition, a plurality of water drain holes 11b are formed on the bottom surface of the upper cover 11.

At least one drain port 10c is formed on the lower surface 10a of each nutrient solution growing port 10. Reference numeral 10b denotes a coupling jaw that sets the coupling position when the nutrient solution cultivation ports 10 are laminated to each other, and reference numeral 4 maintains the stacking state of a plurality of nutrient solution cultivation ports and hangs it on another vehicle (not shown). It is a rope for.

Crop growth sphere (10d) is formed on at least one side of the nutrient solution cultivation port (10). The size of the crop growth zone (10d) is set to a size such that the leaf portion of the crop grown in the culture soil (3) can escape to the outside of the nutrient cultivation port (10). Side 10e of the nutrient solution cultivation port defining the crop growth zone (10d) is inclined upward smoothly to allow the crop to grow naturally upward.

When the nutrient solution is supplied by the injection nozzle (not shown) or the like above the stacked nutrient solution cultivation port of the present embodiment, the nutrient solution is supplied through the nutrient solution supply hole 11a of the upper cover 11 to the nutrient solution supply pipe 10. Filled in 13. The nutrient solution filled in the nutrient solution supply pipe 13 is supplied to the nutrient solution cultivation port 10 of each stage by flowing out through the outlet. The supplied nutrient solution is discharged downward through the water draining port 10c formed in the lower surface 10a of the nutrient solution cultivation port 10.

In this embodiment, to provide an outlet for supplying the nutrient solution to the nutrient solution cultivation port of each stage by forming an enlarged portion extending the cross section of the lower end of the nutrient solution supply pipe to prevent foreign substances from being inserted through the outlet from the outside. However, the present invention is not limited to this, it is possible to extend the cross section of the upper end of the nutrient solution supply pipe, it is also possible to form a plurality of holes in the outer peripheral surface of the upper end or lower end of the nutrient solution supply pipe to allow the nutrient solution to flow out through this hole. .

4 and 5 illustrate a nutrient cultivation device 300 for supporting a plurality of stacked nutrient solution cultivation port according to the present invention and periodically transported on a predetermined closed path.

As shown, the nutrient cultivation device 300 has a "C" type frame 301 extending along a closed loop path, the drain pipe extending in parallel with the frame 301 inside the frame 301 302 is installed. Inside the frame 301, a plurality of movable members 303 including rollers 304 are installed at predetermined intervals and moved on the frame 301. The movable member 303 is coupled to the chain 305 by a conventional coupling method and moves in accordance with the movement of the chain 305. A support rod 306 extending substantially vertically is fixed to the movable member 303 to support the pallet 307 and the nutrient solution growing port 10 described later.

The pallet 307 is fixedly installed on the upper portion of the movable member 303, and the nutrient solution growing port 10 is seated on the pallet 307. A thrust bearing 308 is interposed between the pallet 307 and the nutrient solution cultivation port 10, so that the nutrient solution cultivation port 10 is freely rotatable at that position. Therefore, even if an obstacle is encountered during the movement of the nutrient solution cultivation port 10, the nutrient solution cultivation port 10 may be naturally pivoted by the thrust bearing 308 to minimize the obstruction of the obstacle.

As described above, the stacked nutrient solution cultivation port of the embodiment shown in FIGS. 4 and 5 is characterized in that the stacked nutrient solution cultivation port pivots at the position by installing a thrust bearing 308 at the lower portion thereof. In the present embodiment, a thrust bearing is disclosed for pivot rotation, but it is also possible to adopt technical means for performing the equivalent function.

The present invention is not limited to the nutrient solution cultivation port of the specific shape disclosed in the specification and drawings, it can be adopted nutrient solution cultivation port of various shapes according to the use conditions or design conditions. The number of crop growth zones formed on the side of the nutrient solution cultivation port may also be variously changed according to the circumstances of the crop cultivator.

Stacked nutrient solution cultivation port according to the present invention allows the high efficiency of crop cultivation by promoting the efficient use of space of the facility house by arbitrarily adjusting the number of nutrient solution cultivation port according to the height of the facility house. In particular, the present invention provides an advantage that can easily and efficiently supply the nutrient solution to the nutrient solution cultivation port of each stage laminated through the nutrient solution supply pipe.

Claims (5)

A stacked nutrient cultivation port formed by laminating a plurality of nutrient solution cultivation ports having a culture soil supporting a crop, Each of the plurality of nutrient solution cultivation ports has a cylindrical shape in which the top is open and the bottom thereof is sealed, at least one nutrient solution supply pipe is installed in a substantially vertical direction through the lower surface of the nutrient solution cultivation port, The nutrient solution supply pipe of the two nutrient solution cultivation port is connected to each other at the time of stacking, and the connection portion of the nutrient solution supply pipe adjacent to each other is provided with an outlet through which the nutrient solution can flow out of the nutrient solution supply pipe, Laminated nutrient cultivation port, characterized in that the crop growth sphere is formed on at least one side of each nutrient solution cultivation port. According to claim 1, wherein the crop growth zone is set to a size such that the leaf portion of the crop grown in the culture soil to the outside, the outer surface of the nutrient solution cultivation port defining the crop growth zone is inclined upwards Laminated nutrient solution repot. According to claim 1, The top of the nutrient solution cultivation port located at the top of the nutrient solution cultivation port is further provided with an upper cover, the upper cover has a funnel shape that gradually reduces the cross-sectional area from the top to the bottom, The upper cover is a nutrient solution cultivation port, characterized in that the nutrient solution supply port is formed in each portion corresponding to the nutrient solution supply pipe. The nutrient solution cultivation port of claim 1, wherein a plurality of drainage holes are formed on a lower surface of the nutrient solution cultivation port for discharging the supplied nutrient solution. The nutrient solution cultivation apparatus according to claim 1, wherein a thrust bearing is interposed in the lower part of the stacked nutrient solution cultivation port so that the nutrient solution cultivation port can pivot freely at the position.